Low-input and single-cell methods for Infinium DNA methylation BeadChips

The Infinium BeadChip is the most widely used DNA methylome assay technology for population-scale epigenome profiling. However, the standard workflow requires over 200 ng of input DNA, hindering its application to small cell-number samples, such as primordial germ cells. We developed experimental an...

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Bibliographic Details
Published in:Nucleic acids research 2024-04, Vol.52 (7), p.e38-e38
Main Authors: Lee, Sol Moe, Loo, Christian E, Prasasya, Rexxi D, Bartolomei, Marisa S, Kohli, Rahul M, Zhou, Wanding
Format: Article
Language:English
Subjects:
Animals
CpG Islands
DNA - genetics
DNA - metabolism
DNA Methylation
Epigenomics - methods
Female
Germ Cells - metabolism
Humans
Male
Methods
Mice
Oligonucleotide Array Sequence Analysis - methods
Single-Cell Analysis - methods
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Summary:The Infinium BeadChip is the most widely used DNA methylome assay technology for population-scale epigenome profiling. However, the standard workflow requires over 200 ng of input DNA, hindering its application to small cell-number samples, such as primordial germ cells. We developed experimental and analysis workflows to extend this technology to suboptimal input DNA conditions, including ultra-low input down to single cells. DNA preamplification significantly enhanced detection rates to over 50% in five-cell samples and ∼25% in single cells. Enzymatic conversion also substantially improved data quality. Computationally, we developed a method to model the background signal's influence on the DNA methylation level readings. The modified detection P-value calculation achieved higher sensitivities for low-input datasets and was validated in over 100 000 public diverse methylome profiles. We employed the optimized workflow to query the demethylation dynamics in mouse primordial germ cells available at low cell numbers. Our data revealed nuanced chromatin states, sex disparities, and the role of DNA methylation in transposable element regulation during germ cell development. Collectively, we present comprehensive experimental and computational solutions to extend this widely used methylation assay technology to applications with limited DNA.
ISSN:0305-1048
1362-4962
1362-4962
DOI:10.1093/nar/gkae127